![]() HVFO10X +/-5V (5x Attenuation) Universal Tip Accessory HVFO10X +/-1V (1x Attenuation) Universal Tip Accessory 4 GHz bandwidth, 1.2x attenuation, +/-30V offset, +/-800mV Includes a complete set of solder-in leads, coaxial cables, and PCB mounts. (3048 m) at or below +30 ☌ġ.5 GHz, 0.9 pF, 1 MOhm Active Voltage Probeġ GHz, 0.9 pF, 1 MOhm Active Voltage ProbeĢ00 MHz, 3.5 pF, 1 MOhm Active Differential Probe, ☒0 Vĥ00 MHz, 1.0 pF Active Differential Probe, ☘ Vġ GHz, 1.0 pF Active Differential Probe, ☘ Vġ.5 GHz, 1.0 pF Active Differential Probe, ☘ Vġ50 A, 10 MHz Current Probe - AC/DC, 150 A rms, 500 A Peak Pulse, 2 meter cableĥ00 A, 2 MHz Current Probe - AC/DC, 500 A rms, 700 A Peak Pulse, 6 meter cableģ0A, 50 MHz Current Probe - AC/DC, 30 A rms, 50 A Peak Pulse, 1.5 meter cableģ0A, 100 MHz Current Probe - AC/DC, 30 A rms, 50 A Peak Pulse, 1.5 meter cableģ0A, 50 MHz High Sensitivity Current Probe - AC/DC, 30 A rms, 50 A Peak Pulse, 1.5 meter cableģ0A, 100 MHz High Sensitivity Current Probe - AC/DC, 30 A rms, 50 A Peak Pulse, 1.5 meter cableģ0 A, 10 MHz Current Probe - AC/DC, 30 A rms, 50 A Peak Pulse, 3 meter cableġ50 A, 5 MHz Current Probe - AC/DC, 150 A rms, 500 A Peak Pulse, 6 meter cableĭeskew Calibration Source for CP030, CP030A, CP031, CP031A, AP015, CP150, CP500Ģ50 MHz Passive Probe for WaveSurfer 3000, 10:1, 10 MOhmĥ00 MHz Passive Probe, 5mm, 10:1, 10 MOhmħ00 V, 25 MHz High-Voltage Differential Probe (÷10, ÷100)ġkV, 25 MHz High Voltage Differential Probe with Auto Zero DisconnectġkV, 25 MHz High Voltage Differential Probe without tip Accessories and with Auto Zero DisconnectġkV, 120 MHz High Voltage Differential Probe with Auto Zero DisconnectġkV, 120 MHz High Voltage Differential Probe without tip Accessories and with Auto Zero DisconnectġkV, 80 MHz High Voltage Differential Probe with 6m cable and Auto Zero DisconnectĢkV, 120 MHz High Voltage Differential Probe with Auto Zero DisconnectĢkV, 80 MHz High Voltage Differential Probe with 6m cable and Auto Zero DisconnectĦkV, 100 MHz High Voltage Differential Probe with Auto Zero DisconnectĢkV, 400 MHz High Voltage Differential Probe Upper limit derates to 50% relative humidity (non-condensing) at +50 ☌.ĥ% to 95% relative humidity (non-condensing) as tested per MIL-PRF-28800F Settable from 500 Hz to 1 MHz square waveġ00-240 VAC ☑0% at 50-60 ☑0% Hz 110-120 VAC ☑0% at 400 ±5% Hz Automatic AC Voltage Selectionĥ% to 90% relative humidity (non-condensing) up to ≤ +31 ☌. Automatically detects and supports a variety of compatible probesĪutomatically or manually selected depending on probe usedĭefault is 1kHz square wave, 3.3Vp-p (typical), output to probe hook. Internal timebase common to 4 input channels (For any two ProBus input channels, same v/div settings, typical) Diagnostic Valve Testing / Device Validation / Strain Gage Calibrationġ0.74"H x 14.96"W x 6.30"D (273 mm x 380 mm x 160 mm)Īnalog Bandwidth 50 Ω (-3 dB) (ProBus Input)Īnalog Bandwidth 1 MΩ (-3 dB) (ProBus Input)ġ2 bits up to 15 bits with enhanced resolution (ERES)ġ MΩ: 1 mV/div - 10 V/div, fully variable ĭC Vertical Gain Accuracy (Gain Component of DC Accuracy).Automotive and Device Interoperability Testing. ![]() Protocol Technology Testing and Training.These results open the way to nanoscale optical quantum memories with increased efficiency, bandwidth, and processing capabilities. Pulses with two different frequencies are also stored, confirming frequency-multiplexing capability, and are used to demonstrate the memory high phase fidelity. Storage of light is then demonstrated with an effective coherence lifetime of 5 μs. We first measure a nearly constant Stark coefficient of 50 kHz/(V/cm) across a bandwidth of 15 GHz, which is promising for broadband operation. Here, we report on coherent light storage in Eu 3+:Y 2O 3 nanoparticles using the Stark echo modulation memory (SEMM) quantum protocol. Recent studies have shown that long optical and spin coherence lifetimes can be observed in rare earth doped nanoparticles, opening exciting possibilities over bulk materials, e.g., for enhancing coupling to light and other quantum systems, and material design. Quantum memories for light are essential components in quantum technologies like long-distance quantum communication and distributed quantum computing.
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